Thin film non volatile memory device scalable to small sizes

ABSTRACT

A thin film non volatile memory scalable to small sizes and its fabrication process are disclosed. The thin film memory comprises a thin film transistor control circuitry fabricated on a flexible substrate, together with an optoelectronic cross bar memory comprising a photoconducting material. The thin film non volatile memory can be used in RFID communication tag with the control circuitry further comprises wireless communication circuitry such as an antenna, a receiver, and a transmitter.

FIELD OF THE INVENTION

This invention is related to the provision of small, thin informationappliances or computing devices which have a need for nonvolatilerewriteable digital memory.

BACKGROUND OF THE INVENTION

Currently there is a strong trend toward the development of very lowcost RFID tags, relatively small scale integrated circuits whose inputand output, via radio frequency radiation, uses transponders rather thanreceivers and transmitters, which are cheap enough to achieve ubiquitousdeployment on essentially any object whose location and movement are ofinterest. Such tags would simplify and expedite many tasks, includingkeeping track of and streamlining inventories, preventing theft andcounterfeiting, guaranteeing product authenticity, and monitoringenvironmental conditions experienced by the object. Preferably theyshould be available in the form of labels which can be easily attachedto objects. Some objects, such as secure papers (for example currency,identification documents (including tickets), and certificates or otherlegal documents) are thin and flexible, and any electronics attached tothem should be unobtrusive and preferably invisible.

In many cases, it is desirable for the tags to include some memorybeyond the minimal amount required for simple unique identification ofthe object. For example, a tag may contain information regarding aperson's medical history or special needs, or it might contain extensiveinformation regarding proper handling procedures of a product. Memoryrequirements will vary widely, but often are in the range of 1 kilobyte(kB) to 10 kB, although they may be more or less than these values; sometags are offered with 256 bytes of memory, and some with 256 kB.

Current products do not adequately address these needs. Conventionalsilicon chips are thick (0.5 mm before thinning), brittle, and tooexpensive to meet the <5¢ per tag cost target that most customers quote.The cost of finished CMOS ICs has been approximately $4/cm , or 4¢/mm²,for many years, and while costs per transistor continue to decrease withdevice scaling, areas costs do not. In addition to the basic chip cost,one must include thinning, dicing, placement, and wire-bonding to anantenna. Even after this, the product has problems, including thefragility of the chip-antenna connection and remaining thickness ofsilicon. It will be very difficult to incorporate such devicesunobtrusively into paper documents.

Another major difficulty with existing solutions is that conventionalsilicon nonvolatile memory (which comes in two closely relatedvarieties: EEPROM, or electrically erasable and programmable read-onlymemory, and FLASH memory) is substantially more expensive than CMOSlogic circuitry, and requires a different IC process, so that it isoften not fabricated in the same chip or at the same time or using thesame fabrication processes as logic. Thus, to meet the need for memorydescribed previously, it might be necessary to incorporate another chip,with some suitable connection to the processor. Such connectionssubstantially increase the cost of the product, as well as loweringreliability.

Such nonvolatile memory chips are not only more expensive per unit areathan logic chips or volative memory such as DRAM and SRAM, but theycannot be easily scaled to small sizes such as are desired for RFID tags(as well as other products, such as smart cards). Ignoring for themoment the support circuitry needed for addressing the memory, FLASHrequires one transistor per bit, and so 1 kB (8 kbits) requires 8000transistors, which in a modem (e.g. 0.13 micron design rule) integratedcircuit process will occupy a square less than 50 microns on each side,which is a very small chip that cannot be produced without greatlyincreasing the price per unit area relative to the basic production costof ordinary memory chips. Thus, one is again confronted with thedifficulty of getting the amount of circuitry needed at an acceptableprice.

Scalable memory materials better suitable for this application might beorganic memory materials such as a Zn porphyrin photoconductive thinfilm disclosed in Liu et al., U.S. Pat. No. 5,327,373 (“Optoelectronicmemories with photoconductive thin films”, Jul. 5, 1994) and itsdivision U.S. Pat. No. 5,424,974, hereby incorporated by reference.However, Liu et al. discloses the construction of rigid memory cellswhich are exemplified by devices constructed between glass plates intowhich the active material must be introduced by capillary action.

A desirable solution to these problems would be an integrated circuit(IC) which can be fabricated directly on thin substrates such as paperor paper-thin plastic, along with appropriate memory, in a singlethin-film integrated process so that the antenna connection is made bythe simplest possible techniques, with the greatest possible longevity.It is desirable that the memory be available in the same process, inamounts of about 1 kB to 100 kB (more or less), at a cost that is not amajor increase relative to the cost of the circuit itself.

SUMMARY OF THE INVENTION

The present invention discloses a thin film non-volatile memory devicefabricated on a flexible substrate, comprising a non-volatile memory incommunication with a control circuitry.

The thin film non-volatile memory is an optoelectronic cross bar memorycomprising a photoconductive thin film sandwiched between twoelectrodes, together with a radiation source to provide irradiation tothe photoconductive thin film. Under an electric field and visibleirradiation, non-volatile charges are generated and stored in thephotoconductive thin film and then can be read with appropriate chargesensing circuit. This effect is highly stable and repeatable, and is thebasis for the present invention thin film non-volatile memory.

The control circuitry of the present invention is based on thin filmsilicon technology, in which thin film transistors are fabricated onplastic substrates, preferably in a process amenable to roll-to-rollprocessing. This potentially reduces cost and makes it possible toconveniently transfer the ICs to end-product substrates at an arbitrarydensity and position.

In another embodiment of the invention, the thin film non-volatilememory device is a wireless communication tag in which the controlcircuitry comprises a wireless communication circuit. The wirelesscommunication circuit can employ infrared (IR) communication protocol,or microwave communication protocol, or radio frequency (RF)communication protocol. The wireless communication circuit is preferablya radio frequency identification (RFID) circuitry comprising anintegrated circuit including an antenna, a receiver, a transmitter, anda microprocessor.

The present invention improves substantially to make small memory arrayseconomically, which is desirable for the smart tag/smart cardapplications, with the attendant requirement of thin, inexpensive androbust devices that can be incorporated into paper-thin products. Theinvention scales well to larger sizes as well.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic representation of a cross bar memory array.

FIG. 2 is a schematic representation of an embodiment of the presentinvention.

FIG. 3 is a diagram of a RFID system.

FIG. 4 is a diagram of a RFID tag.

DETAILED DESCRIPTION OF THE INVENTION

Thin film silicon technology, in which thin film transistors arefabricated on plastic substrates, is reasonably well known and welldocumented. The thin film transistors (TFTs) resulting from theseprocesses, which use amorphous silicon (a-Si) as the activesemiconductor material, are suitable for general computationaloperations as well as other applications such as display switchingelements. They can be used to read and write information from EEPROMcells, for example, as well as to make oscillators and logic gates.Because they are fabricated on plastic substrates, the process isamenable to adaptation to roll-to-roll processing with attendant costreductions, and the substrate can be sufficiently thin that it is easilyaccommodated in the thin RFID devices and smart tags or cards which arethe primary (though not exclusive) focus of this invention.

The prior art memory cells, while satisfactory to store digitalinformation, do not meet the needs of the applications cited earlier inmany ways. They are not cheaper than logic; indeed there is at least oneextra processing step (including an extra lithographic masking layer)which adds significant complexity and cost to the manufacture. Theycannot withstand more cycles of rewriting than conventional FLASH memory(ca. 100,000). If they are made on plastic, using conventionallithography processes with their attendant limitations on plasticsubstrates, the transistor footprint would be at least 15 microns ormore, and just 1 kB adds at least 1.5 mm² plus control circuitry to thearea of the device.

Organic memory materials are better suited for this application due tothe cost scalability and the possible fabrication process on a flexiblesubstrate. The disclosed thin film memory is an optoelectronic cross barmemory comprising a photoconductive thin film sandwiched between twoelectrodes, together with a radiation source to provide irradiation tothe photoconductive thin film. In this system, a thin film, about 1.5microns thick, of an organic molecule, preferably a Zn porphyrin withhydrocarbon chain substituents, is sandwiched between two electrodes,one of which must be transparent (for example indium tin oxide, or ITO).When both electrical bias (of about 1-10V) and visible irradiation (atabout 20 microwatts/cm²) are supplied, charge is stored in thephotoconductive porphyrin film. After this “writing” step, if theelectrodes are short circuited under visible irradiation, a currentspike is observed which is far larger than the normal steady statephotocurrent. This effect is highly stable and repeatable, and can beused as the basis for non-volatile solid state memory. In a typicalarchitecture called a cross bar array, the active material is placedbetween crossed electrodes, so that a bit location can be selected asthe intersection of a particular row and column, similar to the pixelsof a matrix-addressed display. This is the same addressing method as isused for other solid state memory arrays such as SRAMs and FLASH, butdoes not require transistors to be located at each crosspoint. It issimilar in this respect to a passive matrix display as implemented, forexample, with certain liquid crystals.

Read and write electronic circuits for the photoconductive memory aredifferent from the circuits for silicon memory such as EEPROM or FLASH.The design and positioning of these circuits with respect to the memorycells is critical, and the photoconductive memory circuits cannot beoptimized by a straightforward application of standard sense amplifiersused for the control of information storage in other media such asdynamic or static random access memories, EEPROMs, FLASH, etc. Due tothe magnitude of the currents that flow upon short-circuiting a small(micron-sized) memory element, attention to minimization of noise andparasitic effects is vital. Thus, it is important to place the input ofthe read amplifier as close to the end of the line (row or column) ofthe matrix as possible. Calculations indicate that in practice, it isdesirable that the lines be no longer than about 1 cm, and theamplifiers should be within microns (less than 100 microns, andpreferably less than 10 microns) of the line ends.

The present invention is a flexible non-volatile memory device buildt ona flexible substrate and comprising thin film transistor controlcircuitry with an optoelectronic cross bar memory in communication withthe control circuitry.

The control circuitry is provided by the thin film transistors (TFTs) ona flexible substrate such as plastic or paper substrate. Because thesetransistors can be fabricated on the same flexible substrate as thememory, and both are thin film devices whose total thickness is only afew microns or less, it is feasible to ensure that the distance betweenthe ends of the memory matrix lines and the inputs of the controllingtransistors is very small, of the order of a few microns.

The optoelectronic memory is based on the principle of generation andstorage of charges in photosensitive organic compounds due to thesimultaneous application of an electric field and a pulse of visiblelight. The optoelectronic memory comprises a memory material, twoelectrodes (a bottom electrode and a top electrode) arranged in a crossbar configuration and sandwiching the photoconductive thin film toprovide an electric field to a selected portion of the photoconductivethin film, and an electromagnetic radiation source to irradiate aportion of the photoconductive thin film. The electromagnetic radiationsource is preferably a visible, infrared or ultraviolet light source.

The memory materials in the optoelectronic memory are generallyphotoconductive thin films in which charge separations within thematerial are generated in the light and then trapped when the light isremoved. The typical photoconductive materials are(metal)(β-decoxyethyl) porphyrins, where metal can be Zn, Cu, Co, Ni andPd, and in C₁₀ derivatives of these compounds, and in non-liquid crystalH₂ octakis (β-decoxyethyl) porphyrin. Other classes of photoconductivematerials include aromatic compounds, phthalocyanines, organometalliccompounds and metal complexes. The photoconductive memory materials arepreferably solid thin films at room temperature and exhibit highphotoconductivity but low dark conductivity, typically less than about10⁻⁷/Ohm-cm for short term memory applications and less than about10⁻¹⁴/Ohm-cm for long term applications. The preferred photoconductivefilm thickness is about 0.3 μm to 3 μm.

FIG. 1 shows the schematic of a cross bar memory array. The topelectrodes 10A, 10B, 10C, 10D are parallelly arranged in one direction,and the bottom electrodes 12A, 12B, 12C are also parallelly arranged inthe direction perpendicular to the top electrodes. The memory material11 is sandwiched between the top electrodes and the bottom electrodes.When a potential is applied between a selected top electrode 10B and aselected bottom electrode 12A, only a section 15 of the memory material11 is under the electric field created by the overlap of the topelectrode 10B and the bottom electrode 12A. Thus the memory cell 15 canbe selectively chosen to read or write.

FIG. 2 shows a schematic of the present invention, comprising a memory20 on a thin film transistor circuitry 30 on a flexible substrate 40.The memory 20 comprises the bottom electrodes 23, the top electrodes 21,the memory material 22, and the light sources 24. The thin filmtransistor 30 comprises the interconnection 31, 32, and 33 connected tothe source 34, the gate 35 and the drain 36 respectively.

In another embodiment of the invention, the thin film non-volatilememory device is a wireless communication tag in which the controlcircuitry comprises a wireless communication circuit. In recent years,automatic identification systems have become popular in many serviceindustries to provide information about price, available goods andproducts. The data is normally stored in a memory chip, and the datatransfer between the tag carrying the data and the stationary reader ispreferably contactless to allow the flexibility and the mobility of theidentification system. The contactless ID systems are often called RFID(radio frequency identification) systems based on the frequency of thetransfer signals. However, the wireless communication circuit can alsoemploy infrared (IR) communication protocol, or microwave communicationprotocol, in addition to radio frequency (RF) communication protocol.

The wireless communication circuit in the present invention preferablycomprises a radio frequency identification (RFID) circuitry comprisingan integrated circuit including an antenna, a receiver, a transmitter,and a microprocessor.

FIG. 3 shows a system mechanism chart for the complete RFID system usinga transponder. The RFID system consists of the host side, which iscomposed of a personal computer 110, a controller 112, an antenna 114and a data carrier 117, such as a RFID tag having an antenna 118. A bus111, such as RS-232, connects computer 11 and controller 112, and acable 113 connects controller 112 and antenna 114. Antenna 114 sendspower and command data 115 to carrier 117 and receives data 116.

The diagram of an RFID tag is shown in FIG. 4. The transponder has asimple structure, which contains a RFID circuitry 119 within a board,and an antenna 118 which functions as a power receiver, datareceiver/transmitter together. The RFID chip 119 may contain a memoryarray 120, an ASIC RF front end processor 121, a central processor CPU133, a battery 130 and an optional display controller 132. Commandinformation and data are transmitted and received between the RFIDcircuitry and the RFID reader through the antenna 118. The CPU 133 maycomprise added security system to prevent unauthorized data accessing.The display 134 is connected to the RFID circuitry through a displaycontroller 132.

The present invention further discloses a method to fabricate a flexiblenon-volatile memory device. The fabrication process starts with aflexible substrate, and continues with the fabrication of a thin filmtransistor control circuitry on the flexible substrate, and thefabrication of an optoelectronic cross bar memory. The thin filmtransistor control circuitry is designed to have a plurality of contactpads for electrical communication with the optoelectronic memory. Thefabrication of the optoelectronic memory comprises the fabrication ofthe bottom electrodes contacting the control circuitry, the depositionof a photoconducting thin film, and the fabrication of top electrodes,also preferably contacting the control circuitry, and the fabrication ofan electromagnetic radiation source for irradiating a portion of thephotoconductive thin film.

The electrodes of the memory can be fabricated on top or on the sides ofthe finished transistors of the control circuitry. It is preferable tofabricate the memory electrodes on top of the control circuitry ratherthan to place the electrodes in a separate area, because it is lessexpensive. If the electrodes and circuitry are placed next to eachother, the cost of the memory per unit area cannot be less than the costof the circuitry (and must in fact be more), since the memory area runsthrough the same process steps (idle) as the TFTs. In the presentconfiguration it is possible to fabricate the crossbar memory array atan estimated cost per bit of 1/75 or less of the cost of equivalenttransistor memory. After the cost of control circuitry is included, thesavings are still quite large.

Although the TFT example described above used amorphous silicontransistors, the invention is not limited to this type. Various types ofsemicrystalline silicon material, described in the literature asmicrocrystalline or nanocrystalline silicon, are known which can bedeposited without further treatment with charge carrier mobilitiesgreater than amorphous silicon, in particular at least 10 cm²/Vs orhigher, and with the mobility of p-type material comparable to that ofn-type. Thus not only can one make circuits which switch at a higherfrequency and can be fabricated more densely, but one can make CMOScircuits which consume much less power than NMOS or PMOS circuits. Thedeposition processes used for this microcrystalline material, whilerequiring higher temperatures (up to around 300° C.) are stillcompatible with the use of plastic substrates and roll-to-rollprocessing.

It is also possible to produce polycrystalline silicon, with mobilitiesin excess of 100 cm²/Vs and up to several hundred, by use of variousannealing techniques. These techniques may make use of an excimer laserto recrystallize the silicon at a relatively low substrate temperature(down to 100° C. in some cases), or they may use small amounts ofcertain metal elements such as nickel, in a process known asmetal-induced crystallization, which can be practiced at temperaturesdown to around 450° C. As with the microcrystalline material, theseprocesses lead to both n and p type devices with comparable performance.

Some of the techniques known in the art for producing polycrystallinesilicon with high mobility, in particular the metal-inducedcrystallization, require temperatures that are incompatible with mostplastics, especially transparent ones. For use in the present invention,at least the top layer substrate must be transparent to visible light.However, these devices can still be incorporated into the subjectinvention. This may be done using the lamination/transfer techniqueusing thermally decomposable polymers, as described in a co-pending U.S.Application entitled “Lamination and delamination technique”,application Ser. No. 10/444,219, filed May 23, 2003, hereby incorporatedby reference. With this technique, transistors can be fabricated on asubstrate which can withstand very high temperatures (it may even be ametal substrate), transferred to a temporary transfer substrate (placedon top of the transistors), and then transferred again onto whateversubstrate is desired. These transfers require only low substratetemperatures (100° C.). The transfer technique is not limited to usewith devices fabricated on flexible substrates: it can be used totransfer devices from rigid substrates, including glass, to flexiblesubstrates. Other techniques for transferring such devices from glass toplastic are also known; for example that described by Seiko-EpsonCorporation, in IEEE Trans. Electron Devices, vol. 49, p. 1353 (2002).

Once the necessary control circuitry has been prepared, the bottomelectrodes of the memory array (which do not need to be transparent) areconveniently fabricated on top of the TFT circuitry, by formation ofvias aligned with the TFT contact pads, followed by deposition of ametal layer that is patterned into array lines. The organic layer isthen deposited by inkjet printing, or alternatively by other printingtechniques capable of depositing a layer of organic liquid (melting ataround 130° C.) in a uniform layer of about 1.5 microns thickness.

Next the top electrodes (ITO or other transparent conductor), withconnections to control electronics, must be formed. In addition, a lightsource, capable of providing at least 10-20 microwatts/cm² of visible,infrared or ultraviolet light through the ITO electrodes, must beavailable. Thus, the top layers are preferably not of the same structureas the bottom, since the circuitry would obscure the light, which willtypically come from an LED or other small, efficient light sourceembedded in the plastic substrate above the circuitry. In thisembodiment, therefore, the array lines are connected to circuitry in thebottom electrode layer by an interconnection which is formed between thelaminated layers.

This may be accomplished either by direct connection of pads at the endsof the array lines with corresponding pads in the bottom layer, or byconnection of contact pads for drive circuitry, especially multiplexers,which may be fabricated in the top layer. The former approach requiressimpler preparation for the top layer (only the electrode lines) butmore demanding alignment to the bottom layer (since the pads cannot belarger than the array linewidth). The latter approach can make use oflarge (many microns wide) pads which are easier to align, but requiressome circuitry to be constructed in the top layer; the minimumrequirement being multiplexer circuits which lessen the number ofinput/output pads. If the array element widths are greater than about 1micron, alignment of the two substrates is feasible and the formermethod may be used.

For array element widths less than about 1 micron, use of the lattermethod would become highly desirable since aligning two separatesubstrates to the required accuracy would be very difficult. In order tokeep the cost of the top layer as low as possible, it will be preferableto use the transfer technique described previously to position thenecessary circuits around the array. In this way it is not necessary toprocess the entire area of the top electrode array through thetransistor fabrication processes. The invention does not require thetransfer process for this purpose, however; it only is useful to reducecost.

When the array is constructed using one of these techniques, the lightsource is conveniently provided by embedding an inorganic LED (forexample GaInN) chip in the top of the top plastic substrate. Such chipscan be obtained in sizes of a few hundred microns. A receptor well canbe made for the LED by mechanical indentation. Contact to this chip forpower supply will be made by a printed conductor line (printed, forexample, by inkjet printing of an ink that is a precursor for aconductive line, as supplied for example by Flint Ink or Parelac). Thisline will be run to a via (preferably made by laser ablation; it can berelatively large, for example 25-50 microns wide, as there is no specialmicroscale constraint on it) through the top substrate down to thebottom substrate and a corresponding pad which connects to the controlcircuitry in the bottom layer. The only purpose of this LED is to be onduring read and write operations, and only two lines need to run to it.

Another method to provide illumination is to couple light into the topsubstrate from the side, using an edge-emitting LED which is located atthe edge of the top substrate tile, and optically connected with a smalldroplet of index-matched polymer applied by inkjet printing. Because theITO electrodes form a periodic array with a spatial periodicity of theorder of the wavelength of visible light, they will scatter some of thewaveguided light out of the plane of the substrate and into theporphyrin. In this case, control circuitry can be fabricated underneaththe top electrodes similarly to that under the bottom electrodes, andthe interconnection of the two is much simpler, because it requires onlya small number of signal lines. These would be transmitted through moreconventional contact pads which might be, for example, 50-100 microns ona side, and these contacts can then be made with commercially availablez-axis adhesives, such as are available from Hitachi Chemical, forexample.

The connection of the LED is again provided by laser drilling of twovias and connection with conductive metal ink precursors, which can beconveniently printed. In order to obtain optimum uniformity ofillumination, it may be necessary to place LEDs on each side of thesquare array.

Both of the alternatives described up to now use a lamination techniqueto put two electrodes together around the photoconducting memorymaterial. It is also possible to deposit the top electrode arraydirectly on the photoconducting memory material. The substratetemperature should be kept to less than 130° C., preferably less thanabout 100° C., in order to remain well below the melting temperature ofthe photoconducting memory material. ITO can be deposited at such lowertemperatures; although its conductivity is not as high as when it isdeposited at higher temperatures, the conductivity required for thepresent memory device is not high. The current flowing through a 4micron line will be of the order of 100 pA, which corresponds to 25mA/cm², assuming 100 nm thick interconnect metal lines.

If such a deposition process is used, it is important to minimize theion bombardment of the organic surface, which can be easily degraded bysuch high energy processes. Careful control of plasma parameters tominimize such bombardment, and the energy of the ions, can be achieved,for example by minimizing rf power. A high-density plasma such as an ECRsystem is advantageous.

ITO is commonly deposited by sputtering, as this process tends to giveoptimum control over material qualities with readily availablecommercial equipment at high deposition rates. However, it may also bedeposited by reactive evaporation, pulsed laser deposition, ion beamassisted deposition, and other techniques, which have been carried outat low substrate temperatures (e.g. room temperature) on polymersubstrates as well as directly on organic light emitting materials. Thecombination of low substrate temperature and low intensity of ionbombardment tends to lead to relatively low ITO conductivity. Inaddition, these techniques tend to produce lower deposition rates thanare commercially desirable. However, it is possible to obtainsatisfactory conductivity at substrate temperatures below 130 C and withlow ion bombardment from these techniques, which may be used to deposita very thin layer. After about 2-5 nm of thickness has been deposited,the organic layer is fully protected from the deleterious effects of ionbombardment, conventional rf or magnetron sputtering can be used tocomplete the required film thickness.

It is also possible to use conducting polymers, such aspoly(ethylenedioxythiophene), or PEDOT, as the top, transparentelectrode. PEDOT can be patterned by photochemical techniques.

It is also possible to interpose a very thin layer of conductinginorganic material between the organic layer and the ITO. Gold andsilver are both examples of metals with high conductivity which remainhighly transparent in thickness of a few nanometers, which is enough toprotect the organic layer from the effects of conventional ITOdeposition.

It is also possible to use other transparent conducting oxides than ITO,for example Al-doped ZnO, Sb-doped SnO, and others which are well knownin the art.

In both cases, there is no need either for circuitry in the top layer,or for any complex interlayer connection process. The ends of the toparray lines are connected to corresponding contact pads in the bottomelectrode layer by ordinary planar processing.

The advantage of this invention is that the cost of processing thelayers required to form the memory is substantially less than thatrequired for TFTs, since only two conventional lithographic steps(patterning of the electrodes) is required, and fewer (and less complex)depositions as well. The memory can also be made more dense, since thelateral density is determined only by the lithography of the array, andso the area occupied by a bit can easily be made much smaller than thearea occupied by a transistor plus floating gate and associated addresslines, as required for FLASH memory. A rough estimate of the costsavings is that the cost per unit area should be in the vicinity of ⅓ ofthe cost of transistor fabrication (based primarily on the reduction inlithography), and the density of bits, using the same lithographictools, should be about a factor of 25 greater; hence the cost per bitshould be around 1/75 as much.

The invention improves substantially on the prior art in that it is nowpossible to make small memory arrays economically, which is what isdesired for the smart tag/smart card applications, with the attendantrequirement of thin, inexpensive and robust devices that can beincorporated into paper-thin products. The invention scales well tolarger sizes as well.

If amorphous silicon transistors are used, the performance of the memoryis currently limited by the charge carrier mobility to less than 1 MHzclock frequency. This is not a limitation for the intended applicationtoday, since readout times of approximately 1 second for the entirememory of 1 kB-10 kB is well within the capability of the circuitry.

Another feature of amorphous silicon is the fact that only n-dopeddevices are realistic in current technology, since p-doped devices areeven slower (by two or three orders of magnitude). Again, this featuredoes not affect the intended application since the major concern ofhaving only n-type devices is power consumption (CMOS does not consumepower unless actually switching, while NMOS does), and the RFID-typeproducts are not operated continuously for long periods.

Another limitation of amorphous silicon is the fact that only n-dopeddevices are realistic, since p-doped devices are even slower (by two orthree orders of magnitude). Again, this limitation does not affect theintended application since the major concern of having only n-typedevices is power consumption (CMOS does not consume power unlessactually switching, while NMOS does), and the RFID-type products are notoperated continuously for long periods.

The invention is not confined to the use of amorphous silicon, however,although that represents the currently cheapest and most availablecircuit technology. Other circuit solutions, including microcrystallineand polycrystalline silicon, are also applicable and appropriate, as hasalready been discussed. These can implement CMOS, and work at many MHzclock speeds.

1. A flexible non-volatile memory device comprising a flexiblesubstrate; a thin film transistor control circuitry formed on theflexible substrate; and an optoelectronic cross bar memory incommunication with the control circuitry, the optoelectronic cross barmemory comprising a photoconductive thin film; a plurality of bottomelectrodes and a plurality of top electrodes arranged in a cross barconfiguration, sandwiching the photoconductive thin film to provide anelectric field to selected portion of the photoconductive thin film; andan electromagnetic radiation source to irradiate a portion of thephotoconductive thin film; wherein the photoconductive thin film storestrapped charges generated by the electromagnetic radiation.
 2. A deviceas in claim 1 wherein the flexible substrate is a plastic or papersubstrate.
 3. A device as in claim 1 wherein the photoconductive filmthickness is between 1 to 2 μm.
 4. A device as in claim 1 wherein thephotoconductive film is (metal)(beta-decoxyethyl)porphyrins wherein themetal is selected from a group consisting of Cu, Co, Ni, Pd.
 5. A deviceas in claim 1 wherein the photoconductive film iszinc-octakis(beta-decoxyethyl)porphyrins.
 6. A device as in claim 1wherein the photoconductive film is phthalocyanine, an aromaticcompound, or an organo-metallic compound.
 7. A device as in claim 1wherein the electromagnetic radiation source is a visible, infrared orultraviolet light source.
 8. A device as in claim 1 wherein theoptoelectronic cross bar memory is positioned on top of thin filmtransistor control circuitry.
 9. A device as in claim 1 wherein theoptoelectronic cross bar memory is positioned on the flexible substrate,beside the thin film transistor control circuitry.
 10. A device as inclaim 1 wherein the top electrode material is transparent to theelectromagnetic radiation.
 11. A device as in claim 1 wherein the topelectrode material is indium tin oxide, another inorganic transparentconducting oxide, a conducting polymer, or poly(ethylenedioxythiophene).12. A device as in claim 1 wherein the electromagnetic radiation sourceis positioned on top of the top electrodes.
 13. A device as in claim 1wherein the electromagnetic radiation source is positioned on the edgeof the top electrodes.
 14. A RFID device comprising a semiconductorsubstrate; a transistor control circuitry formed on the semiconductorsubstrate comprising a wireless communication circuit; and anoptoelectronic cross bar memory in communication with the controlcircuitry, the optoelectronic cross bar memory comprising aphotoconductive thin film; a plurality of bottom electrodes and aplurality of top electrodes arranged in a cross bar configuration,sandwiching the photoconductive thin film to provide an electric fieldto selected portion of the photoconductive thin film; and anelectromagnetic radiation source to irradiate a portion of thephotoconductive thin film; wherein the photoconductive thin film storestrapped charges generated by the electromagnetic radiation.
 15. A deviceas in claim 14 wherein the wireless communication circuit employs IRcommunication protocol.
 16. A device as in claim 14 wherein the wirelesscommunication circuit employs microwave communication protocol.
 17. Adevice as in claim 14 wherein the wireless communication circuit employsradio frequency communication protocol.
 18. A device as in claim 14further comprising a battery to supply power to the whole circuitry. 19.A device as in claim 18 wherein the battery is a thin film battery. 20.A device as in claim 14 wherein the wireless communication circuitcomprises an antenna.
 21. A device as in claim 14 wherein the flexiblesubstrate is a plastic or paper substrate.
 22. A device as in claim 14wherein the photoconductive film thickness is between 1 to 2 μm.
 23. Adevice as in claim 14 wherein the photoconductive film is(metal)(beta-decoxyethyl)porphyrins wherein the metal is selected from agroup consisting of Cu, Co, Ni, Pd.
 24. A device as in claim 14 whereinthe photoconductive film is zinc-octakis(beta-decoxyethyl)porphyrins.25. A device as in claim 14 wherein the photoconductive film isphthalocyanine, an aromatic compound, or an organo-metallic compound.26. A device as in claim 14 wherein the electromagnetic radiation sourceis a visible, infrared or ultraviolet light source.